Quantifying uncertainties in climate data: measurement limitations of naturally ventilated thermometer screens

Climate science depends on accurate air temperature measurement. To achieve this, well ventilated thermometers protected from direct sunlight and precipitation are needed, commonly through using louvred enclosures known as screens or shields. Maintaining good natural ventilation is critical for accu...

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Bibliographic Details
Published in:Environmental Research Communications 2021-06, Vol.3 (6), p.61005
Main Authors: Harrison, R Giles, Burt, Stephen D
Format: Article
Language:English
Subjects:
Air temperature
Climate
climate data
Climate science
Climatic data
Radiation
radiation error
Screens
Stevenson screen
Temperature
Temperature measurement
thermometer time response
Thermometers
Time response
Uncertainty
Ventilation
Wind
Wind speed
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Summary:Climate science depends on accurate air temperature measurement. To achieve this, well ventilated thermometers protected from direct sunlight and precipitation are needed, commonly through using louvred enclosures known as screens or shields. Maintaining good natural ventilation is critical for accurate measurements. Ventilation effects on air temperature uncertainties are quantified here using an aspirated thermometer as a reference, for air temperatures spanning −2.8 °C to 35.5 °C. Of 81462 5 min mean temperature values obtained, 50% were within ±0.07 °C of the reference and only 2% lay beyond −0.66 °C to 0.47 °C, where negative values represent the naturally ventilated screen thermometer underestimating air temperature. Larger absolute differences arose from a combination of radiation exchange and time response effects, which are separated here. Firstly, using 20s data, the exponential time response of the naturally ventilated thermometer is shown to vary with wind speed u as u −0.5 , and exceeds the conventional 1 min averaging time for wind speeds up to 5 ms −1 (at 2 m height), increasing to at least 15 min when calm. Secondly, radiation exchange effects (both by day and by night) dominated at low wind speeds (
ISSN:2515-7620
2515-7620
DOI:10.1088/2515-7620/ac0d0b